发布时间:2023-03-31 文章分类:电脑基础 投稿人:樱花 字号: 默认 | | 超大 打印

文章目录

  • 1 前言
  • 2 数据准备
  • 3 数据预处理
  • 4 Bert-BiLSTM-CRF模型
  • 5 Bert-CRF模型
  • 6 模型训练
  • 7 结果评估
  • 8 训练集流水线
  • 9 测试集流水线
  • 10 记录遇到的一些坑
  • 11 完整代码

1 前言

猿创征文|信息抽取(2)——pytorch实现Bert-BiLSTM-CRF、Bert-CRF模型进行实体抽取

论文参考:
1 Neural Architectures for Named Entity Recognition
2 Attention is all you need
3 BERT: Pre-training of Deep Bidirectional Transformers for
Language Understanding
4 Bidirectional LSTM-CRF Models for Sequence Tagging
使用数据集:
https://www.datafountain.cn/competitions/529/ranking
Tips:文章可能存在一些漏洞,欢迎留言指出

2 数据准备

使用了transformers和seqeval库
安装方法:
huggingface-transformers

conda install -c huggingface transformers

seqeval

pip install seqeval -i https://pypi.tuna.tsinghua.edu.cn/simple

代码

import pandas as pd
import torch
from torch import optim
from torch.utils.data import DataLoader
from tqdm import tqdm
from bert_bilstm_crf import Bert_BiLSTM_CRF, NerDataset, NerDatasetTest
from bert_crf import Bert_CRF
from transformers import AutoTokenizer, BertTokenizer
from seqeval.metrics import f1_score
# 路径
TRAIN_PATH = './dataset/train_data_public.csv'
TEST_PATH = './dataset/test_public.csv'
MODEL_PATH1 = './model/bert_bilstm_crf.pkl'
MODEL_PATH2 = '../model/bert_crf.pkl'
# 超参数
MAX_LEN = 64
BATCH_SIZE = 16
EPOCH = 5
# 预设
# 设备
DEVICE = "cuda:0" if torch.cuda.is_available() else "cpu"
# tag2index
tag2index = {
    "O": 0,  # 其他
    "B-BANK": 1, "I-BANK": 2,  # 银行实体
    "B-PRODUCT": 3, "I-PRODUCT": 4,  # 产品实体
    "B-COMMENTS_N": 5, "I-COMMENTS_N": 6,  # 用户评论,名词
    "B-COMMENTS_ADJ": 7, "I-COMMENTS_ADJ": 8  # 用户评论,形容词
}
index2tag = {v: k for k, v in tag2index.items()}

3 数据预处理

== 流程==

  1. 使用
    s
    e
    r
    i
    e
    s
    .
    a
    p
    p
    l
    y
    (
    l
    i
    s
    t
    )
    \textcolor{red}{series.apply(list)}
    series.apply(list)
    函数将str转化为list格式
  2. 加载bert预训练tokenizer,使用
    e
    n
    c
    o
    d
    e
    _
    p
    l
    u
    s
    \textcolor{red}{encode\_plus}
    encode_plus
    函数对每一个text进行encode
  3. 如果是训练集,则执行如下操作:首先按照空格将每一个tag分割,并转化为索引列表,对每一个index_list,按照长度大于MAX_LEN裁剪,小于MAX_LEN填充的规则,合并为一个list,最后转化为tensor格式

代码

# 预处理
def data_preprocessing(dataset, is_train):
    # 数据str转化为list
    dataset['text_split'] = dataset['text'].apply(list)
    # token
    tokenizer = BertTokenizer.from_pretrained('bert-base-chinese')
    texts = dataset['text_split'].array.tolist()
    token_texts = []
    for text in tqdm(texts):
        tokenized = tokenizer.encode_plus(text=text,
                                          max_length=MAX_LEN,
                                          return_token_type_ids=True,
                                          return_attention_mask=True,
                                          return_tensors='pt',
                                          padding='max_length',
                                          truncation=True)
        token_texts.append(tokenized)
    # 训练集有tag,测试集没有tag
    tags = None
    if is_train:
        dataset['tag'] = dataset['BIO_anno'].apply(lambda x: x.split(sep=' '))
        tags = []
        for tag in tqdm(dataset['tag'].array.tolist()):
            index_list = [0] + [tag2index[t] for t in tag] + [0]
            if len(index_list) < MAX_LEN:  # 填充
                pad_length = MAX_LEN - len(index_list)
                index_list += [tag2index['O']] * pad_length
            if len(index_list) > MAX_LEN:  # 裁剪
                index_list = index_list[:MAX_LEN-1] + [0]
            tags.append(index_list)
        tags = torch.LongTensor(tags)
    return token_texts, tags

4 Bert-BiLSTM-CRF模型

猿创征文|信息抽取(2)——pytorch实现Bert-BiLSTM-CRF、Bert-CRF模型进行实体抽取
相对于Bert-CRF,中间添加了双向LSTM层。相对BiLSTM-CRF,相当于前面的word_embedding层替换为了bert预训练模型。
代码

import torch
from torch import nn
from torchcrf import CRF
from transformers import BertModel
from torch.utils.data import Dataset
class Bert_BiLSTM_CRF(nn.Module):
    def __init__(self, tag2index):
        super(Bert_BiLSTM_CRF, self).__init__()
        self.tagset_size = len(tag2index)
        # bert层
        self.bert = BertModel.from_pretrained('bert-base-chinese')
        # config = self.bert.config
        # lstm层
        self.lstm = nn.LSTM(input_size=768, hidden_size=128, num_layers=1, batch_first=True, bidirectional=True)
        # dropout层
        self.dropout = nn.Dropout(p=0.1)
        # Dense层
        self.dense = nn.Linear(in_features=256, out_features=self.tagset_size)
        # CRF层
        self.crf = CRF(num_tags=self.tagset_size)
        # 隐藏层
        self.hidden = None
    # 负对数似然损失函数
    def neg_log_likelihood(self, emissions, tags=None, mask=None, reduction=None):
        return -1 * self.crf(emissions=emissions, tags=tags, mask=mask, reduction=reduction)
    def forward(self, token_texts, tags):
        """
        token_texts:{"input_size": tensor,  [batch, 1, seq_len]->[batch, seq_len]
                    "token_type_ids": tensor,  [batch, 1, seq_len]->[batch, seq_len]
                     "attention_mask": tensor  [batch, 1, seq_len]->[batch, seq_len]->[seq_len, batch]
                     }
        tags:  [batch, seq_len]->[seq_len, batch]
        bert_out:  [batch, seq_len, hidden_size(768)]->[seq_len, batch, hidden_size]
        self.hidden:  [num_layers * num_directions, hidden_size(128)]
        out:  [seq_len, batch, hidden_size * 2(256)]
        lstm_feats:  [seq_len, batch, tagset_size]
        loss:  tensor
        predictions:  [batch, num]
        """
        texts, token_type_ids, masks = token_texts['input_ids'], token_texts['token_type_ids'], token_texts['attention_mask']
        texts = texts.squeeze(1)
        token_type_ids = token_type_ids.squeeze(1)
        masks = masks.squeeze(1)
        bert_out = self.bert(input_ids=texts, attention_mask=masks, token_type_ids=token_type_ids)[0]
        bert_out = bert_out.permute(1, 0, 2)
        # 检测设备
        device = bert_out.device
        # 初始化隐藏层参数
        self.hidden = (torch.randn(2, bert_out.size(0), 128).to(device),
                       torch.randn(2, bert_out.size(0), 128).to(device))
        out, self.hidden = self.lstm(bert_out, self.hidden)
        lstm_feats = self.dense(out)
        # 格式转换
        masks = masks.permute(1, 0)
        masks = masks.clone().detach().bool()
        # masks = torch.tensor(masks, dtype=torch.uint8)
        # 计算损失值和预测值
        if tags is not None:
            tags = tags.permute(1, 0)
            loss = self.neg_log_likelihood(lstm_feats, tags, masks, 'mean')
            predictions = self.crf.decode(emissions=lstm_feats, mask=masks)  # [batch, 任意数]
            return loss, predictions
        else:
            predictions = self.crf.decode(emissions=lstm_feats, mask=masks)
            return predictions

Dataset

class NerDataset(Dataset):
    def __init__(self, token_texts, tags):
        super(NerDataset, self).__init__()
        self.token_texts = token_texts
        self.tags = tags
    def __getitem__(self, index):
        return {
            "token_texts": self.token_texts[index],
            "tags": self.tags[index] if self.tags is not None else None,
        }
    def __len__(self):
        return len(self.token_texts)
class NerDatasetTest(Dataset):
    def __init__(self, token_texts):
        super(NerDatasetTest, self).__init__()
        self.token_texts = token_texts
    def __getitem__(self, index):
        return {
            "token_texts": self.token_texts[index],
            "tags": 0
        }
    def __len__(self):
        return len(self.token_texts)

前向传播分析
token_texts:{
“input_size”: tensor, [batch, 1, seq_len]->[batch, seq_len]
“token_type_ids”: tensor, [batch, 1, seq_len]->[batch, seq_len]
“attention_mask”: tensor [batch, 1, seq_len]->[batch, seq_len]->[seq_len, batch]
}
tags: [batch, seq_len]->[seq_len, batch]
bert_out: [batch, seq_len, hidden_size(768)]->[seq_len, batch, hidden_size]
self.hidden: [num_layers * num_directions, hidden_size(128)]
out: [seq_len, batch, hidden_size * 2(256)]
lstm_feats: [seq_len, batch, tagset_size]
loss: tensor
predictions: [batch, num]

5 Bert-CRF模型

猿创征文|信息抽取(2)——pytorch实现Bert-BiLSTM-CRF、Bert-CRF模型进行实体抽取

from torch import nn
from torchcrf import CRF
from transformers import BertModel
class Bert_CRF(nn.Module):
    def __init__(self, tag2index):
        super(Bert_CRF, self).__init__()
        self.tagset_size = len(tag2index)
        # bert层
        self.bert = BertModel.from_pretrained('bert-base-chinese')
        # dense层
        self.dense = nn.Linear(in_features=768, out_features=self.tagset_size)
        # CRF层
        self.crf = CRF(num_tags=self.tagset_size)
        # 隐藏层
        self.hidden = None
    def neg_log_likelihood(self, emissions, tags=None, mask=None, reduction=None):
        return -1 * self.crf(emissions=emissions, tags=tags, mask=mask, reduction=reduction)
    def forward(self, token_texts, tags):
        """
        token_texts:{"input_size": tensor,  [batch, 1, seq_len]->[batch, seq_len]
                    "token_type_ids": tensor,  [batch, 1, seq_len]->[batch, seq_len]
                     "attention_mask": tensor  [batch, 1, seq_len]->[batch, seq_len]->[seq_len, batch]
                     }
        tags:  [batch, seq_len]->[seq_len, batch]
        bert_out:  [batch, seq_len, hidden_size(768)]->[seq_len, batch, hidden_size]
        feats:  [seq_len, batch, tagset_size]
        loss:  tensor
        predictions:  [batch, num]
        """
        texts, token_type_ids, masks = token_texts.values()
        texts = texts.squeeze(1)
        token_type_ids = token_type_ids.squeeze(1)
        masks = masks.squeeze(1)
        bert_out = self.bert(input_ids=texts, attention_mask=masks, token_type_ids=token_type_ids)[0]
        bert_out = bert_out.permute(1, 0, 2)
        feats = self.dense(bert_out)
        # 格式转换
        masks = masks.permute(1, 0)
        masks = masks.clone().detach().bool()
        # 计算损失之和预测值
        if tags is not None:
            tags = tags.permute(1, 0)
            loss = self.neg_log_likelihood(feats, tags, masks, 'mean')
            predictions = self.crf.decode(emissions=feats, mask=masks)
            return loss, predictions
        else:
            predictions = self.crf.decode(emissions=feats, mask=masks)
            return predictions

前向传播分析
token_texts:{
“input_size”: tensor, [batch, 1, seq_len]->[batch, seq_len]
“token_type_ids”: tensor, [batch, 1, seq_len]->[batch, seq_len]
“attention_mask”: tensor [batch, 1, seq_len]->[batch, seq_len]->[seq_len, batch]
}
tags: [batch, seq_len]->[seq_len, batch]
bert_out: [batch, seq_len, hidden_size(768)]->[seq_len, batch, hidden_size]
feats: [seq_len, batch, tagset_size]
loss: tensor
predictions: [batch, num]

6 模型训练

# 训练
def train(train_dataloader, model, optimizer, epoch):
    for i, batch_data in enumerate(train_dataloader):
        token_texts = batch_data['token_texts'].to(DEVICE)
        tags = batch_data['tags'].to(DEVICE)
        loss, predictions = model(token_texts, tags)
        optimizer.zero_grad()
        loss.backward()
        optimizer.step()
        if i % 200 == 0:
            micro_f1 = get_f1_score(tags, predictions)
            print(f'Epoch:{epoch} | i:{i} | loss:{loss.item()} | Micro_F1:{micro_f1}')

7 结果评估

# 计算f1值
def get_f1_score(tags, predictions):
    tags = tags.to('cpu').data.numpy().tolist()
    temp_tags = []
    final_tags = []
    for index in range(BATCH_SIZE):
        # predictions先去掉头,再去掉尾
        predictions[index].pop()
        length = len(predictions[index])
        temp_tags.append(tags[index][1:length])
        predictions[index].pop(0)
        # 格式转化,转化为List(str)
        temp_tags[index] = [index2tag[x] for x in temp_tags[index]]
        predictions[index] = [index2tag[x] for x in predictions[index]]
        final_tags.append(temp_tags[index])
    f1 = f1_score(final_tags, predictions, average='micro')
    return f1

Bert-BiLSTM-CRF

GPU_NAME:NVIDIA GeForce RTX 3060 Laptop GPU | Memory_Allocated:413399040
Epoch:0 | i:0 | loss:58.75139236450195 | Micro_F1:0.0
Epoch:0 | i:200 | loss:26.20857048034668 | Micro_F1:0.0
Epoch:0 | i:400 | loss:18.385879516601562 | Micro_F1:0.0
Epoch:1 | i:0 | loss:20.496620178222656 | Micro_F1:0.0
Epoch:1 | i:200 | loss:15.421577453613281 | Micro_F1:0.0
Epoch:1 | i:400 | loss:11.486358642578125 | Micro_F1:0.0
Epoch:2 | i:0 | loss:14.486601829528809 | Micro_F1:0.0
Epoch:2 | i:200 | loss:10.369649887084961 | Micro_F1:0.18867924528301888
Epoch:2 | i:400 | loss:8.056020736694336 | Micro_F1:0.5652173913043479
Epoch:3 | i:0 | loss:14.958343505859375 | Micro_F1:0.41025641025641024
Epoch:3 | i:200 | loss:9.968450546264648 | Micro_F1:0.380952380952381
Epoch:3 | i:400 | loss:8.947534561157227 | Micro_F1:0.5614035087719299
Epoch:4 | i:0 | loss:9.189300537109375 | Micro_F1:0.5454545454545454
Epoch:4 | i:200 | loss:8.673486709594727 | Micro_F1:0.43999999999999995
Epoch:4 | i:400 | loss:6.431578636169434 | Micro_F1:0.6250000000000001

Bert-CRF

GPU_NAME:NVIDIA GeForce RTX 3060 Laptop GPU | Memory_Allocated:409739264
Epoch:0 | i:0 | loss:57.06057357788086 | Micro_F1:0.0
Epoch:0 | i:200 | loss:12.05904483795166 | Micro_F1:0.0
Epoch:0 | i:400 | loss:13.805888175964355 | Micro_F1:0.39393939393939387
Epoch:1 | i:0 | loss:9.807424545288086 | Micro_F1:0.4905660377358491
Epoch:1 | i:200 | loss:8.098043441772461 | Micro_F1:0.509090909090909
Epoch:1 | i:400 | loss:7.059831619262695 | Micro_F1:0.611111111111111
Epoch:2 | i:0 | loss:6.629759788513184 | Micro_F1:0.6133333333333333
Epoch:2 | i:200 | loss:3.593130350112915 | Micro_F1:0.6896551724137931
Epoch:2 | i:400 | loss:6.8786163330078125 | Micro_F1:0.6666666666666666
Epoch:3 | i:0 | loss:5.009466648101807 | Micro_F1:0.6969696969696969
Epoch:3 | i:200 | loss:2.9549810886383057 | Micro_F1:0.8450704225352113
Epoch:3 | i:400 | loss:3.3801448345184326 | Micro_F1:0.868421052631579
Epoch:4 | i:0 | loss:5.864352226257324 | Micro_F1:0.626865671641791
Epoch:4 | i:200 | loss:3.308518409729004 | Micro_F1:0.7666666666666667
Epoch:4 | i:400 | loss:4.221902847290039 | Micro_F1:0.7000000000000001

分析
进行了5个epoch的训练
数据集比较小,只有7000多条数据,因此两个模型效果拟合效果相对BiLSTM+CRF模型提升不大。而添加了双向LSTM层之后,模型效果反而有所下降。

8 训练集流水线

注意学习率要设置小一点(小于1e-5),否则预测结果均为0,不收敛。

def execute():
    # 加载训练集
    train_dataset = pd.read_csv(TRAIN_PATH, encoding='utf8')
    # 数据预处理
    token_texts, tags = data_preprocessing(train_dataset, is_train=True)
    # 数据集装载
    train_dataset = NerDataset(token_texts, tags)
    train_dataloader = DataLoader(dataset=train_dataset, batch_size=BATCH_SIZE, shuffle=True, num_workers=4)
    # 构建模型
    # model = Bert_BiLSTM_CRF(tag2index=tag2index).to(DEVICE)
    model = Bert_CRF(tag2index=tag2index).to(DEVICE)
    optimizer = optim.AdamW(model.parameters(), lr=1e-6)
    print(f"GPU_NAME:{torch.cuda.get_device_name()} | Memory_Allocated:{torch.cuda.memory_allocated()}")
    # 模型训练
    for i in range(EPOCH):
        train(train_dataloader, model, optimizer, i)
    # 保存模型
    torch.save(model.state_dict(), MODEL_PATH2)

9 测试集流水线

# 测试集预测实体标签
def test():
    # 加载数据集
    test_dataset = pd.read_csv(TEST_PATH, encoding='utf8')
    # 数据预处理
    token_texts, _ = data_preprocessing(test_dataset, is_train=False)
    # 装载测试集
    dataset_test = NerDatasetTest(token_texts)
    test_dataloader = DataLoader(dataset=dataset_test, batch_size=BATCH_SIZE, shuffle=False, num_workers=4)
    # 构建模型
    # model = Bert_BiLSTM_CRF(tag2index).to(DEVICE)
    model = Bert_CRF(tag2index).to(DEVICE)
    model.load_state_dict(torch.load(MODEL_PATH2))
    # 模型预测
    model.eval()
    predictions_list = []
    with torch.no_grad():
        for i, batch_data in enumerate(test_dataloader):
            token_texts = batch_data['token_texts'].to(DEVICE)
            predictions = model(token_texts, None)
            predictions_list.extend(predictions)
    print(len(predictions_list))
    print(len(test_dataset['text']))
    # 将预测结果转换为文本格式
    entity_tag_list = []
    index2tag = {v: k for k, v in tag2index.items()}  # 反转字典
    for i, (text, predictions) in enumerate(zip(test_dataset['text'], predictions_list)):
        # 删除首位和最后一位
        predictions.pop()
        predictions.pop(0)
        text_entity_tag = []
        for c, t in zip(text, predictions):
            if t != 0:
                text_entity_tag.append(c + index2tag[t])
        entity_tag_list.append(" ".join(text_entity_tag))  # 合并为str并加入列表中
    print(len(entity_tag_list))
    result_df = pd.DataFrame(data=entity_tag_list, columns=['result'])
    result_df.to_csv('./data/result_df3.csv')

猿创征文|信息抽取(2)——pytorch实现Bert-BiLSTM-CRF、Bert-CRF模型进行实体抽取
结果好像存在一些问题。。。

10 记录遇到的一些坑

(1)模型预测结果全为O
原因:按照之前的模型,AdamW优化器学习率设置0.001,学习率过高,导致梯度下降过程中落入了局部最低点。
解决方法:重新设置学习率为1e-6
(2)transformers的AdamW显示过期
解决方法:直接使用torch.optim的AdamW即可
(3)transformers库在ubuntu上无法使用
原因:缺少依赖
解决方法:

apt-get update
apt-get install libssl1.0.0 libssl-dev

使用此代码在服务器终端上跑完后,仍会报错,原因未知,暂时用os.system()嵌入到代码中,在windows系统中无此报错。
(4)笔记本(联想R7000P2021)运行代码温度过高(最高95度)
解决方法:先用均衡模式(CPU不睿频)跑,温度只有六七十度,然后开启野兽模式跑一段时间,温度高了再切换为均衡模式。

11 完整代码

import pandas as pd
import torch
from torch import optim
from torch.utils.data import DataLoader
from tqdm import tqdm
from bert_bilstm_crf import Bert_BiLSTM_CRF, NerDataset, NerDatasetTest
from bert_crf import Bert_CRF
from transformers import AutoTokenizer, BertTokenizer
from seqeval.metrics import f1_score
# 路径
TRAIN_PATH = './dataset/train_data_public.csv'
TEST_PATH = './dataset/test_public.csv'
MODEL_PATH1 = './model/bert_bilstm_crf.pkl'
MODEL_PATH2 = '../model/bert_crf.pkl'
# 超参数
MAX_LEN = 64
BATCH_SIZE = 16
EPOCH = 5
# 预设
# 设备
DEVICE = "cuda:0" if torch.cuda.is_available() else "cpu"
# tag2index
tag2index = {
    "O": 0,  # 其他
    "B-BANK": 1, "I-BANK": 2,  # 银行实体
    "B-PRODUCT": 3, "I-PRODUCT": 4,  # 产品实体
    "B-COMMENTS_N": 5, "I-COMMENTS_N": 6,  # 用户评论,名词
    "B-COMMENTS_ADJ": 7, "I-COMMENTS_ADJ": 8  # 用户评论,形容词
}
index2tag = {v: k for k, v in tag2index.items()}
# 训练
def train(train_dataloader, model, optimizer, epoch):
    for i, batch_data in enumerate(train_dataloader):
        token_texts = batch_data['token_texts'].to(DEVICE)
        tags = batch_data['tags'].to(DEVICE)
        loss, predictions = model(token_texts, tags)
        optimizer.zero_grad()
        loss.backward()
        optimizer.step()
        if i % 200 == 0:
            micro_f1 = get_f1_score(tags, predictions)
            print(f'Epoch:{epoch} | i:{i} | loss:{loss.item()} | Micro_F1:{micro_f1}')
# 计算f1值
def get_f1_score(tags, predictions):
    tags = tags.to('cpu').data.numpy().tolist()
    temp_tags = []
    final_tags = []
    for index in range(BATCH_SIZE):
        # predictions先去掉头,再去掉尾
        predictions[index].pop()
        length = len(predictions[index])
        temp_tags.append(tags[index][1:length])
        predictions[index].pop(0)
        # 格式转化,转化为List(str)
        temp_tags[index] = [index2tag[x] for x in temp_tags[index]]
        predictions[index] = [index2tag[x] for x in predictions[index]]
        final_tags.append(temp_tags[index])
    f1 = f1_score(final_tags, predictions, average='micro')
    return f1
# 预处理
def data_preprocessing(dataset, is_train):
    # 数据str转化为list
    dataset['text_split'] = dataset['text'].apply(list)
    # token
    tokenizer = BertTokenizer.from_pretrained('bert-base-chinese')
    texts = dataset['text_split'].array.tolist()
    token_texts = []
    for text in tqdm(texts):
        tokenized = tokenizer.encode_plus(text=text,
                                          max_length=MAX_LEN,
                                          return_token_type_ids=True,
                                          return_attention_mask=True,
                                          return_tensors='pt',
                                          padding='max_length',
                                          truncation=True)
        token_texts.append(tokenized)
    # 训练集有tag,测试集没有tag
    tags = None
    if is_train:
        dataset['tag'] = dataset['BIO_anno'].apply(lambda x: x.split(sep=' '))
        tags = []
        for tag in tqdm(dataset['tag'].array.tolist()):
            index_list = [0] + [tag2index[t] for t in tag] + [0]
            if len(index_list) < MAX_LEN:  # 填充
                pad_length = MAX_LEN - len(index_list)
                index_list += [tag2index['O']] * pad_length
            if len(index_list) > MAX_LEN:  # 裁剪
                index_list = index_list[:MAX_LEN-1] + [0]
            tags.append(index_list)
        tags = torch.LongTensor(tags)
    return token_texts, tags
# 执行流水线
def execute():
    # 加载训练集
    train_dataset = pd.read_csv(TRAIN_PATH, encoding='utf8')
    # 数据预处理
    token_texts, tags = data_preprocessing(train_dataset, is_train=True)
    # 数据集装载
    train_dataset = NerDataset(token_texts, tags)
    train_dataloader = DataLoader(dataset=train_dataset, batch_size=BATCH_SIZE, shuffle=True, num_workers=4)
    # 构建模型
    # model = Bert_BiLSTM_CRF(tag2index=tag2index).to(DEVICE)
    model = Bert_CRF(tag2index=tag2index).to(DEVICE)
    optimizer = optim.AdamW(model.parameters(), lr=1e-6)
    print(f"GPU_NAME:{torch.cuda.get_device_name()} | Memory_Allocated:{torch.cuda.memory_allocated()}")
    # 模型训练
    for i in range(EPOCH):
        train(train_dataloader, model, optimizer, i)
    # 保存模型
    torch.save(model.state_dict(), MODEL_PATH2)
# 测试集预测实体标签
def test():
    # 加载数据集
    test_dataset = pd.read_csv(TEST_PATH, encoding='utf8')
    # 数据预处理
    token_texts, _ = data_preprocessing(test_dataset, is_train=False)
    # 装载测试集
    dataset_test = NerDatasetTest(token_texts)
    test_dataloader = DataLoader(dataset=dataset_test, batch_size=BATCH_SIZE, shuffle=False, num_workers=4)
    # 构建模型
    model = Bert_BiLSTM_CRF(tag2index).to(DEVICE)
    model.load_state_dict(torch.load(MODEL_PATH2))
    # 模型预测
    model.eval()
    predictions_list = []
    with torch.no_grad():
        for i, batch_data in enumerate(test_dataloader):
            token_texts = batch_data['token_texts'].to(DEVICE)
            predictions = model(token_texts, None)
            predictions_list.extend(predictions)
    print(len(predictions_list))
    print(len(test_dataset['text']))
    # 将预测结果转换为文本格式
    entity_tag_list = []
    index2tag = {v: k for k, v in tag2index.items()}  # 反转字典
    for i, (text, predictions) in enumerate(zip(test_dataset['text'], predictions_list)):
        # 删除首位和最后一位
        predictions.pop()
        predictions.pop(0)
        text_entity_tag = []
        for c, t in zip(text, predictions):
            if t != 0:
                text_entity_tag.append(c + index2tag[t])
        entity_tag_list.append(" ".join(text_entity_tag))  # 合并为str并加入列表中
    print(len(entity_tag_list))
    result_df = pd.DataFrame(data=entity_tag_list, columns=['result'])
    result_df.to_csv('./data/result_df3.csv')
if __name__ == '__main__':
    execute()
    test()